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Carotenoid hydroxylase from Haematococcus pluvialis: cDNA sequence, regulation and functional complementation
Biochimica et Biophysica Acta 1446 (1999) 203^212 www.elsevier.com/locate/bba
Carotenoid hydroxylase from Haematococcus pluvialis: cDNA sequence, regulation and functional complementation Hartmut Linden * Lehrstuhl fu«r Physiologie und Biochemie der P£anzen, Universita«t Konstanz, D-78434 Konstanz, Germany Received 15 March 1999; accepted 2 June 1999
Abstract A cDNA homologous to L-carotene hydroxylase from Arabidopsis thaliana was isolated from the green alga Haematococcus pluvialis. The predicted amino acid sequence for this enzyme shows homology to the three known plant L-carotene hydroxylases from Arabidopsis thaliana and from Capsicum annuum (38% identity) and to prokaryote carotenoid hydroxylases (32^34% identities). Heterologous complementation using E. coli strains which were genetically engineered to produce carotenoids indicated that the H. pluvialis L-carotene hydroxylase was able to catalyse not only the conversion of Lcarotene to zeaxanthin but also the conversion of canthaxanthin to astaxanthin. Furthermore, Northern blot analysis revealed increased L-carotene hydroxylase mRNA steady state levels after induction of astaxanthin biosynthesis. In accordance with the latter results, it is proposed that the carotenoid hydroxylase characterized in the present publication is involved in the biosynthesis of astaxanthin during cyst cell formation of H. pluvialis. ß 1999 Elsevier Science B.V. All rights reserved. Keywords: Astaxanthin; L-Carotene; Green alga; Hydroxylase; Zeaxanthin; (Haematococcus pluvialis)
1. Introduction In some green algae such as Dunaliella bardawil and Haematococcus pluvialis, accumulation of carotenoids is induced by various environmental stress factors including high light, high salinity and nutrient deprivation [1,2]. Thus, large amounts of the keto carotenoid astaxanthin (3,3P-dihydroxy-L-carotene4,4P-dione) are produced in the green alga Haematococcus pluvialis under unfavourable culture conditions such as nitrogen or phosphate de¢ciency and increased light intensities [3,4]. This massive produc-
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tion of astaxanthin in H. pluvialis (up to 3% of the dry weight [4]) is normally but not necessarily accompanied by morphological changes of bi£agellate vegetative cells into non-mobile cyst cells. In contrast to the situation in higher plants where the carotenoids are produced in chloroplasts and chromoplasts, the accumulation of astaxanthin in H. pluvialis seems to occur in the cytoplasm [5]. During this extraplastidic accumulation of astaxanthin, the general structure of the chloroplast remains intact as shown by electron microscopy. It is not clear at present whether astaxanthin (or the precursors for astaxanthin biosynthesis) are synthesized in the chloroplast and then transported to the cytoplasm or whether biosynthesis occurs both in the chloroplast and in the cytoplasm. The induction and regulation of astaxanthin biosyn-
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thesis in H. pluvialis has recently received considerable attention due to the increasing use of astaxanthin as a source for pigmentation for ¢sh aquacultures and due to a putative function in cancer prevention and as free radical quencher [4]. Carotenoids are synthesized by all photosynthetic organisms. They play an important role as light harvesting pigments and protect the photosynthetic apparatus from photooxidative damage under excess light conditions (reviewed in [6]). The early steps of carotenoid biosynthesis which consist of the biosynthesis of phytoene from isoprenoid precursors as well as the desaturation of phytoene to lycopene, followed by two cyclization reactions converting lycopene into L-carotene have been extensively studied and the corresponding genes have been isolated from bacteria and plants [6,7]. Several of the enzymes involved in xanthophyll biosynthesis, carotenoids modi¢ed with oxygen containing groups, have also been characterized, e.g., the L-carotene hydroxylase which converts L-carotene into L-cryptoxanthin and zeaxanthin from bacteria [8^10] and higher plants [11,12]. Moreover, some genes encoding L-carotene ketolase which catalyses the conversion of L-carotene to canthaxanthin via echinenone have been isolated not only from bacteria but also from H. pluvialis [13^ 15]. In enzymatic studies both in vitro and in vivo in Escherichia coli using the Haematococcus L-carotene ketolase, it was shown that the latter enzyme essentially converted L-carotene into canthaxanthin [14,16^18]. In contrast, the presence of hydroxy groups (L-cryptoxanthin and zeaxanthin) either reduced or prevented the formation of keto groups. These ¢ndings led to a putative biosynthetic pathway with the most favourable route to astaxanthin being via echinenone, canthaxanthin and adonirubin as outlined in Fig. 1. The same route has also been proposed previously after the detection of the latter intermediates following the inhibition of astaxanthin biosynthesis by diphenylamine [19]. Consequently, the existence of a carotenoid hydroxylase in H. pluvialis has been predicted which is capable of converting canthaxanthin into astaxanthin and which is active during the induction of astaxanthin biosynthesis in response to environmental stress situations [14]. In spite of many reports published on the accumulation of carotenoids in H. pluvialis in response to
high light and unfavourable culture conditions, little research has been carried out on the molecular process of the regulation of astaxanthin biosynthesis. Only recently has the expression of two IPP isomerases as well as the expression of lycopene L-cyclase and L-carotene ketolase during the induction of astaxanthin biosynthesis by light been examined [20]. The lycopene cyclase did not show higher protein levels, whereas the mRNA steady state levels of L-carotene ketolase and of the IPP isomerases were upregulated in response to higher light intensities. In the present publication, the isolation and characterization of a cDNA coding for a Haematococcus carotenoid hydroxylase is described. Heterologous complementation and astaxanthin production in E. coli as well as the increased mRNA steady state levels during cyst cell formation indicated that this carotenoid hydroxylase is involved in the biosynthesis of astaxanthin in H. pluvialis. 2. Materials and methods 2.1. Strains, plasmids and growth conditions Haematococcus pluvialis Flotow NIES-144 was obtained from the National Institute for Environmental Studies (NIES), Tsukuba, Japan. The basal medium (pH 6.8) for growth of H. pluvialis contained 1.2 g sodium acetate, 2.0 g yeast extract, 0.4 g L-asparagine, 0.2 g MgCl2 c6H2 O, 0.01 g FeSO4 c7H2 O and 0.02 g CaCl2 c2H2 O per litre [3]. H. pluvialis was grown at 20³C under a dark/light cycle of 12 h light (20 WE/m2 s) and 12 h dark for 4 days. For induction of astaxanthin biosynthesis and cyst cell formation, sodium acetate and FeSO4 were added after 4 days at a ¢nal concentration of 45 mM and 450 WM, respectively. After addition, light conditions were changed to continuous light at 125 WE/m2 s according to [13]. E. coli strain JM101 was used as a host for the complementation experiments with plasmids pACCAR16vcrtX, pRKbkt1 and L-carotene hydroxylase. Plasmid pACCAR16vcrtX harbours the carotenoid biosynthesis genes crtE, crtB, crtI, and crtY from Erwinia uredovora and resulted in biosynthesis of Lcarotene [8,15]. Plasmid pRKbkt1 carries the L-carotene ketolase (bkt) cDNA from H. pluvialis [13]. Cultures of E. coli JM101 containing the di¡erent
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plasmids were grown in LB medium at 28³C for 48 h and ampicillin (50 Wg/ml), chloramphenicol (30 Wg/ ml), tetracycline (10 Wg/ml) and isopropyl-L-D-thiogalactopyranoside (0.5 mM) were added as required [21]. 2.2. Construction of H. pluvialis VcDNA expression libraries, screening and DNA sequencing For the construction of cDNA libraries, H. pluvialis RNAs were extracted either from vegetative cells or from cyst cells (induction of cyst cell formation for 8 h) as described below. After puri¢cation of poly(A)RNA and synthesis of cDNAs, two VZAP expression libraries were constructed with the cDNA Synthesis and ZAP-cDNA Gigapack III Gold Cloning kit (Stratagene). A cDNA fragment of L-carotene hydroxylase from Arabidopsis thaliana [11] (bases 121 to 743; kindly provided by Dr. S. Ro«mer, Konstanz, Germany) which was ampli¢ed by reverse transcription^polymerase chain reaction using speci¢c oligonucleotides was employed as a heterologous probe in the screening procedure. Probe labelling and plaque hybridization was carried out according to the instructions in the DIG Nonradioactive Nucleic Acid Labelling and Detection system (Boehringer Mannheim). After puri¢cation and in vivo excision using the ExAssist/SOLR system (Stratagene), the positive cDNA clone was further utilized for complementation experiments and DNA sequencing. The nucleotide sequence of the H. pluvialis L-carotene hydroxylase cDNA was determined for both strands using the Abi Prism Dye Terminator Cycle Sequencing Ready Reaction kit (Perkin^ Elmer). The analysis of nucleotide and derived amino acid sequences as well as multiple alignments were carried out using the PC/Gene program (IntelliGenetics). Minor changes for multiple alignments were subsequently introduced. 2.3. Northern blot analysis After 4 days of growth, the H. pluvialis cells were collected by centrifugation either directly or after varying induction times of astaxanthin biosynthesis. The cells were frozen and subsequently powdered under liquid nitrogen. RNA was then isolated according to the miniprep RNA extraction procedure
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described by Sokolowsky et al. [22]. For Northern blot analysis, total RNA (10 Wg) was denatured in formaldehyde, electrophoresed on a 1% agarose gel containing 6% formaldehyde, transferred to Hybond N+ membrane (Amersham) and hybridized in the presence of 50% formamide after addition of 1.5U106 cpm/ml of 32 P-labelled probes. 2.4. Carotenoid extraction and HPLC analysis For the isolation of carotenoids (carotenes and hydroxylated products) from E. coli, the freeze-dried cells were extracted twice with acetone at 55³C for 15 min. The combined extracts were then partitioned into diethylether/petrol (b.p. 35^80³C) (1:9, v/v), evaporated to dryness and separated on a nucleosil 100-5 C18 column (Macherey^Nagel) with acetonitrile/methanol/2-propanol (85:10:5, v/v/v) as the eluent for the separation of L-carotene and hydroxylated products. For the separation of keto carotenoids, acetonitrile/methanol/H2 O (50:44:6, v/ v/v) was applied as an eluent 1 for 22 min and methanol as the eluent 2. Spectra were recorded directly from elution peaks using a Waters 994 diode array detector. Total carotenoids from Haematococcus cells were isolated as already described and astaxanthin as well as astaxanthin esters were quanti¢ed after HPLC separation. Standards for HPLC analysis such as L-carotene, astaxanthin and zeaxanthin were purchased either from Sigma or Roth. 2.5. Nucleotide sequence accession number The EMBL GenBank accession number for the L-carotene hydroxylase cDNA reported in this paper is AF162276. 3. Results and discussion 3.1. Isolation and DNA- and amino acid sequence of L-carotene hydroxylase from H. pluvialis For the isolation of carotenoid biosynthesis genes from H. pluvialis, two cDNA libraries were constructed in the VZap vector. For the vegetative cell library, RNA was extracted after 4 days of growth under low light conditions. The cyst cell library was
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Fig. 1. Proposed astaxanthin biosynthetic pathway in H. pluvialis according to in vivo complementation studies [16]. Bold arrows indicate enzymatic reactions carried out by L-carotene hydroxylase. All the other reactions are either carried out by L-carotene ketolase (solid arrows) or indicate biosynthetic steps unlikely to occur in H. pluvialis (broken arrows). Additional non-accumulating intermediates (e.g., hydroxyechinenone) were omitted.
constructed using RNA which was extracted after induction of cyst cell formation and astaxanthin biosynthesis for an additional 8 h. Induction was carried out by the addition of acetate and ferrous sulfate according to [3]. The addition of acetate seems to cause a high carbon/nitrogen ratio and consequently a relative de¢ciency in nitrogen. The addition of Fe2 is presumed to result in the formation of active oxygen species via the Fenton reaction [3]. Under these conditions, the morphological change of vegetative cells into cyst cells and the biosynthesis of astaxan-
thin were shown to proceed rapidly. Therefore, the mRNA steady state levels of genes speci¢cally involved in the biosynthesis of astaxanthin could be expected to be high at this stage. For the screening procedure, a cDNA fragment of A. thaliana L-carotene hydroxylase was used which had been isolated and characterized previously [11]. In spite of extensive screening of both the vegetative and the cyst cell library, only one positive plaque was isolated from the cyst cell library. Sequence analysis of the entire cDNA insert revealed a 1608 base pair (bp) long
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Fig. 2. Nucleotide and deduced amino acid sequences of the cDNA encoding L-carotene hydroxylase from H. pluvialis. The ¢rst ATG codon in frame is underlined.
fragment including a 23 bp poly(A) tail. The DNA sequence shared signi¢cant identity with the A. thaliana L-carotene hydroxylase cDNA (59% identity over 346 bp). The cDNA revealed one long open
reading frame which extends from the beginning of the cDNA to a stop codon at base 969 (Fig. 2), indicating that this cDNA may not represent the entire open reading frame. The ¢rst ATG start codon
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Fig. 3. Amino acid sequence alignment of the H. pluvialis L-carotene hydroxylase with the known bacterial and plant L-carotene hydroxylases. Amino acid residues which were either well or perfectly conserved in all sequences are indicated by (.) and (*) below the alignment, respectively. Identical amino acids are printed in bold. Conserved histidine motifs are shown above the sequence. A highly conserved motif is underlined. GenBank accession numbers: A. thaliana, U58919; C. annuum Ca1, Y09225; C. annuum Ca2, Y09722; Alcaligenes sp., D58422; Agrobacterium aurianticum, D58420; Erwinia herbicola, M87280; Erwinia uredovora, D90087.
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for this open reading frame was found at nucleotide position 90. In contrast to the higher plant cDNAs encoding L-carotene hydroxylases, the H. pluvialis cDNA showed a very long nucleotide sequence which is due to a long 3P non-coding region (A. thaliana, 1156 bp; C. annuum, 1112 bp and 1044 bp; H. pluvialis, 1608 bp). An alignment of the deduced amino acid sequence of H. pluvialis L-carotene hydroxylase with other carotene hydroxylases from bacteria and higher plants is shown in Fig. 3. The only carotene hydroxylase sequence which has been omitted in Fig. 3 is the L-carotene hydroxylase of the cyanobacteria Synechocystis sp. PCC6803 [15]. This protein revealed only limited sequence homologies to the L-carotene hydroxylases presented in Fig. 3. In contrast, it was reported to show sequence similarities with the L-carotene ketolase of H. pluvialis, an enzyme which is also involved in astaxanthin biosynthesis (Fig. 1). The predicted amino acid sequence for the H. pluvialis L-carotene hydroxylase revealed an overall homology to the three known plant L-carotene hydroxylases from A. thaliana and from C. annuum (38% identity). A lower homology was found to the prokaryote carotenoid hydroxylases (32^34% identities). The four conserved histidine motifs which have been described [12] and the highly conserved so called motif 1 (amino acids HDGLVHXRXP; [11]) are also present in the H. pluvialis protein. These histidine residues were proposed to be involved in iron binding and their importance for the hydroxylation reaction was proven by site-directed mutagenesis [12]. The H. pluvialis L-carotene hydroxylase revealed a N-terminal extension when compared to the bacterial hydroxylases which has also been observed for the higher plant enzymes. Due to putative localization of the higher plant enzymes in the chloroplast, a function as chloroplast targeting sequence has been assumed [11]. However, the sequence similarities between the algal and plant enzymes extend for about 50 amino acid residues towards the N-terminus indicating an involvement of this sequence in the enzymatic activity (Fig. 3). In support of this idea, it has been shown for the Arabidopsis L-carotene hydroxylase that a part of this N-terminal region is necessary for a fully functional enzyme. Furthermore, a carotenoid hydroxylase implicated in astaxanthin biosynthesis may be expected to be localized in the cytosol as has been proposed for the
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Fig. 4. HPLC separation of carotenoid pigments extracted from E. coli cells carrying either plasmid pACCAR16vcrtX only (A) or plasmid pACCAR16vcrtX together with L-carotene hydroxylase from H. pluvialis (B). The following carotenoids were identi¢ed by their absorption spectra and their retention times, as compared to standards: L-carotene, L-cryptoxanthin and zeaxanthin, all revealing absorption maxima at 425 nm, 452 nm and 480 nm.
H. pluvialis L-carotene ketolase [13]. Further experiments are required to address these questions. 3.2. Heterologous complementation of L-carotene hydroxylase in E. coli In order to examine the catalytic activities of the H. pluvialis L-carotene hydroxylase, E. coli strains were used which had been genetically engineered to produce various carotenoids [13,15]. Transformation of plasmid pACCAR16vcrtX which contained the crtE, crtB, crtI and crtY genes from E. uredovora in E. coli resulted in the accumulation of L-carotene (Fig. 4A). After co-transformation of plasmids pACCAR16vcrtX and the plasmid containing the entire L-carotene hydroxylase cDNA from H. pluvialis, the corresponding E. coli transformants were shown to produce L-cryptoxanthin and zeaxanthin (Fig. 4B). The conversion ratio between L-carotene and the hydroxylated products was similar to the conversion ratio which has previously been described for the higher plant hydroxylases from Arabidopsis and Capsicum [11,12]. In enzyme studies using the L-carotene ketolase
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from Haematococcus, it was shown that the latter enzyme mainly converted L-carotene into canthaxanthin (Fig. 1, [14,16^18]). However, the hydroxylated carotenoids such as L-cryptoxanthin and zeaxanthin were only poor substrates for the ketolase. Therefore, a carotenoid hydroxylase which is involved in astaxanthin biosynthesis should also be capable of catalysing the conversion from canthaxanthin to astaxanthin as previously proposed [14]. To investigate this hypothesis, a second co-transformation experiment was designed. Co-transformation of plasmid pACCAR16vcrtX and plasmid pRKbkt1 (containing the Haematococcus L-carotene ketolase [13]) in E. coli resulted in the biosynthesis of the keto carotenoid canthaxanthin in addition to small amounts of L-carotene (Fig. 5A, peaks 4 and 6). After transfor-
Fig. 6. Expression of L-carotene hydroxylase cDNA in H. pluvialis and astaxanthin biosynthesis before and after induction of cyst cell formation. The H. pluvialis L-carotene hydroxylase was used as speci¢c probe (A). For comparison, total RNA on the agarose gel was stained with ethidium bromide (B). In addition, the accumulation of astaxanthin was examined (C).
Fig. 5. HPLC separation of carotenoid pigments extracted from E. coli cells after transformation with plasmids pACCAR16vcrtX and pRKbkt1 (A) and with plasmids pACCAR16vcrtX, pRKbkt1 and L-carotene hydroxylase from H. pluvialis (B). For comparison, an astaxanthin standard was also separated (C). HPLC separation was carried out using acetonitrile/methanol/H2 O (50:44:6, v/v/v) as eluent 1 for 22 min and methanol as eluent 2. The following carotenoids were identi¢ed by their absorption spectra and their retention times, as compared to standards: 1, astaxanthin (absorbance maximum, 480 nm); 2, probably adonixanthin (470 nm); 3, zeaxanthin (425 nm, 452 nm, 480 nm); 4, canthaxanthin (475 nm) ; 5, L-cryptoxanthin (425 nm, 452 nm, 480 nm), 6, L-carotene (425 nm, 452 nm, 480 nm).
mation of this E. coli strain with a third plasmid containing the Haematococcus carotenoid hydroxylase cDNA fragment, several carotenoids were detected by HPLC analysis (Fig. 5B). First of all, canthaxanthin (peak 4), L-cryptoxanthin (peak 5) and zeaxanthin (peak 3) were identi¢ed. These xanthophylls correspond to the intermediate and end products of L-carotene ketolase and hydroxylase, respectively, as shown in Figs. 4B and 5A. In addition, the E. coli transformant produced astaxanthin (Fig. 5B, peak 1). Astaxanthin was identi¢ed by the absorbance maximum of 480 nm and the retention time which corresponded to the retention time of a purchased astaxanthin standard (Fig. 5C, peak 1). Furthermore, a second additional xanthophyll was
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found which was identi¢ed as adonixanthin because of a higher retention time in comparison to astaxanthin and the spectrum with only one maximum at 470 nm (Fig. 5B, peak 2). In consequence, the Haematococcus carotenoid hydroxylase seems to be a multifunctional enzyme, which accepts not only Lcarotene but also keto carotenoids such as canthaxanthin as possible substrates. This is in accordance with results from in vitro studies of L-carotene ketolase from H. pluvialis which showed that the ketolase has a higher catalytic speci¢city for non-hydroxylated substrates such as L-carotene and echinenone [17]. Due to this higher catalytic speci¢ty of L-carotene ketolase, adonixanthin and zeaxanthin detected in Fig. 5 are proposed to represent ¢nal products which can not be further converted to astaxanthin. This also means that adonixanthin is not derived from zeaxanthin but is produced via other keto carotenoid intermediates (hydroxyechinenone). The biosynthesis of astaxanthin in E. coli has also been reported using bacterial carotenoid hydroxylases from E. uredovora which revealed the same enzymatic activities as the carotenoid hydroxylase from H. pluvialis. [9,13,14]. In contrast, the hydroxylation of keto carotenoids has not yet been described for the higher plant hydroxylases from Arabidopsis and Capsicum [11,12]. 3.3. Expression of L-carotene hydroxylase during the induction of astaxanthin biosynthesis in H. pluvialis In Northern blot analysis, the expression pattern of L-carotene hydroxylase was examined using RNA extracted from cells at di¡erent stages of cyst cell and astaxanthin biosynthesis induction (Fig. 6). No transcript was detected in the vegetative cells (Fig. 6A). In contrast, the Haematococcus cells clearly revealed a hydroxylase transcript 3 h after induction of astaxanthin biosynthesis and cyst cell formation by high light and by the addition of ferrous sulfate and acetate. An additional strong increase in the hydroxylase mRNA steady state levels was observed after 6 h induction time. For comparison, the accumulation of astaxanthin was also examined over the same period of induction (Fig. 6C). Only a very small increase was observed after 3 h induction, whereas a signi¢-
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cant increase in astaxanthin was found after an induction for 6 h. The latter result is a con¢rmation of the kinetics of astaxanthin accumulation already published in which a ¢rst signi¢cant increase of astaxanthin was observed several hours after induction [3]. The maximum astaxanthin accumulation was reported to occur only 2 to 3 days after the induction of cyst cell formation. In conclusion, the Haematococcus L-carotene hydroxylase characterized in the present publication reveals all the features of a carotenoid hydroxylase involved in astaxanthin biosynthesis. Firstly, the enzyme was shown to be capable of astaxanthin biosynthesis in complementation experiments. Furthermore, the transcript of the carotenoid hydroxylase revealed a strong induction during the process of astaxanthin accumulation. An additional function in the biosynthesis of zeaxanthin during vegetative growth can be presumed although no transcript was detected (Fig. 6A). A minor undetectable expression of the same transcript in the vegetative cells may be su¤cient for xanthophyll production. The fact that the Haematococcus carotenoid hydroxylase revealed a bifunctional catalytic activity hydroxylating not only canthaxanthin but also L-carotene, as shown in Fig. 4, supports the latter presumption. Alternatively, another as yet not identi¢ed hydroxylase may exist which is transcribed only in vegetative cells and which is responsible for the biosynthesis of the xanthophylls involved in photosynthesis. Acknowledgements This work was only possible due to the generous support from Prof. Dr. P. Bo«ger, Konstanz, Germany. I am grateful to Dr. M. Albrecht, Frankfurt, Germany for the gift of the plasmid pRKbkt1. Furthermore, I wish to thank F. Kirsch, Konstanz, Germany for her help in the laboratory. Due thanks are expressed to Dr. N. Misawa, Kirin Brewery Co., Yokohama, Japan for his advice on the H. pluvialis cDNA library construction and for the gift of the plasmids for complementation in E. coli. I am also grateful to Dr. S. Ro«mer, Konstanz, Germany for providing the cDNA fragment of L-carotene hydroxylase from Arabidopsis thaliana.
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of carotenoid hydroxylases from pepper fruits (Capsicum annuum L.), Biochim. Biophys. Acta 1391 (1998) 320^328. S. Kajiwara, T. Kakizono, T. Saito, K. Kondo, T. Ohtani, N. Nishio, S. Nagai, N. Misawa, Isolation and functional identi¢cation of a novel cDNA for astaxanthin biosynthesis from Haematococcus pluvialis, and astaxanthin synthesis in Escherichia coli, Plant Mol. Biol. 29 (1995) 343^552. T. Lotan, J. Hirschberg, Cloning and expression in Escherichia coli of the gene encoding L-C-4-oxygenase, that converts L-carotene to the ketocarotenoid canthaxanthin in Haematococcus pluvialis, FEBS Lett. 364 (1995) 125^128. N. Misawa, S. Kajiwara, K. Kondo, A. Yokoyama, Y. Satomi, T. Saito, W. Miki, T. Ohtani, Canthaxanthin biosynthesis by the conversion of methylene to keto groups in a hydrocarbon L-carotene by a single gene, Biochem. Biophys. Res. Commun. 209 (1995) 867^876. J. Breitenbach, N. Misawa, S. Kajiwara, G. Sandmann, Expression in Escherichia coli and properties of the carotene ketolase from Haematococcus pluvialis, FEMS Microbiol. Lett. 140 (1996) 241^246. P.D. Fraser, H. Shimada, N. Misawa, Enzymatic con¢rmation of reactions involved in routes to astaxanthin formation, elucidated using a direct substrate in vitro assay, Eur. J. Biochem. 252 (1998) 229^236. P.D. Fraser, Y. Miura, N. Misawa, In vitro characterization of astaxanthin biosynthetic enzymes, J. Biol. Chem. 272 (1997) 6128^6135. L. Fan, A. Vonshak, R. Gabbay, J. Hirschberg, Z. Cohen, S. Boussiba, The biosynthetic pathway of astaxanthin in the green alga Haematococcus pluvialis as indicated by inhibition with diphenylamine, Plant Cell Physiol. 36 (1995) 1519^1524. Z. Sun, F.X. Cunningham, E. Gantt, Di¡erential expression of two isopentenyl pyrophosphate isomerases and enhanced carotenoid accumulation in a unicellular chlorophyte, Proc. Natl. Acad. Sci. USA 95 (1998) 11482^11488. J. Sambrook, E.F. Fritsch, T. Maniatis, Molecular Cloning : A Laboratory Manual, 2nd ed., Cold Spring Harbor Laboratory Press, Cold Spring Harbour, NY, 1989. V. Sokolowsky, R. Kaldenho¡, M. Ricci, V.E.A. Russo, Fast and reliable mini-prep RNA extraction from Neurospora crassa, Fungal Genet. Newslett. 36 (1990) 41^43.
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Carotenoid hydroxylase from Haematococcus pluvialis: cDNA sequence, regulation and functional complementation Hartmut Linden * Lehrstuhl fu«r Physiologie und Biochemie der P£anzen, Universita«t Konstanz, D-78434 Konstanz, Germany Received 15 March 1999; accepted 2 June 1999
Abstract A cDNA homologous to L-carotene hydroxylase from Arabidopsis thaliana was isolated from the green alga Haematococcus pluvialis. The predicted amino acid sequence for this enzyme shows homology to the three known plant L-carotene hydroxylases from Arabidopsis thaliana and from Capsicum annuum (38% identity) and to prokaryote carotenoid hydroxylases (32^34% identities). Heterologous complementation using E. coli strains which were genetically engineered to produce carotenoids indicated that the H. pluvialis L-carotene hydroxylase was able to catalyse not only the conversion of Lcarotene to zeaxanthin but also the conversion of canthaxanthin to astaxanthin. Furthermore, Northern blot analysis revealed increased L-carotene hydroxylase mRNA steady state levels after induction of astaxanthin biosynthesis. In accordance with the latter results, it is proposed that the carotenoid hydroxylase characterized in the present publication is involved in the biosynthesis of astaxanthin during cyst cell formation of H. pluvialis. ß 1999 Elsevier Science B.V. All rights reserved. Keywords: Astaxanthin; L-Carotene; Green alga; Hydroxylase; Zeaxanthin; (Haematococcus pluvialis)
1. Introduction In some green algae such as Dunaliella bardawil and Haematococcus pluvialis, accumulation of carotenoids is induced by various environmental stress factors including high light, high salinity and nutrient deprivation [1,2]. Thus, large amounts of the keto carotenoid astaxanthin (3,3P-dihydroxy-L-carotene4,4P-dione) are produced in the green alga Haematococcus pluvialis under unfavourable culture conditions such as nitrogen or phosphate de¢ciency and increased light intensities [3,4]. This massive produc-
* Fax: +49-7531-883042; E-mail: [email protected]
tion of astaxanthin in H. pluvialis (up to 3% of the dry weight [4]) is normally but not necessarily accompanied by morphological changes of bi£agellate vegetative cells into non-mobile cyst cells. In contrast to the situation in higher plants where the carotenoids are produced in chloroplasts and chromoplasts, the accumulation of astaxanthin in H. pluvialis seems to occur in the cytoplasm [5]. During this extraplastidic accumulation of astaxanthin, the general structure of the chloroplast remains intact as shown by electron microscopy. It is not clear at present whether astaxanthin (or the precursors for astaxanthin biosynthesis) are synthesized in the chloroplast and then transported to the cytoplasm or whether biosynthesis occurs both in the chloroplast and in the cytoplasm. The induction and regulation of astaxanthin biosyn-
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thesis in H. pluvialis has recently received considerable attention due to the increasing use of astaxanthin as a source for pigmentation for ¢sh aquacultures and due to a putative function in cancer prevention and as free radical quencher [4]. Carotenoids are synthesized by all photosynthetic organisms. They play an important role as light harvesting pigments and protect the photosynthetic apparatus from photooxidative damage under excess light conditions (reviewed in [6]). The early steps of carotenoid biosynthesis which consist of the biosynthesis of phytoene from isoprenoid precursors as well as the desaturation of phytoene to lycopene, followed by two cyclization reactions converting lycopene into L-carotene have been extensively studied and the corresponding genes have been isolated from bacteria and plants [6,7]. Several of the enzymes involved in xanthophyll biosynthesis, carotenoids modi¢ed with oxygen containing groups, have also been characterized, e.g., the L-carotene hydroxylase which converts L-carotene into L-cryptoxanthin and zeaxanthin from bacteria [8^10] and higher plants [11,12]. Moreover, some genes encoding L-carotene ketolase which catalyses the conversion of L-carotene to canthaxanthin via echinenone have been isolated not only from bacteria but also from H. pluvialis [13^ 15]. In enzymatic studies both in vitro and in vivo in Escherichia coli using the Haematococcus L-carotene ketolase, it was shown that the latter enzyme essentially converted L-carotene into canthaxanthin [14,16^18]. In contrast, the presence of hydroxy groups (L-cryptoxanthin and zeaxanthin) either reduced or prevented the formation of keto groups. These ¢ndings led to a putative biosynthetic pathway with the most favourable route to astaxanthin being via echinenone, canthaxanthin and adonirubin as outlined in Fig. 1. The same route has also been proposed previously after the detection of the latter intermediates following the inhibition of astaxanthin biosynthesis by diphenylamine [19]. Consequently, the existence of a carotenoid hydroxylase in H. pluvialis has been predicted which is capable of converting canthaxanthin into astaxanthin and which is active during the induction of astaxanthin biosynthesis in response to environmental stress situations [14]. In spite of many reports published on the accumulation of carotenoids in H. pluvialis in response to
high light and unfavourable culture conditions, little research has been carried out on the molecular process of the regulation of astaxanthin biosynthesis. Only recently has the expression of two IPP isomerases as well as the expression of lycopene L-cyclase and L-carotene ketolase during the induction of astaxanthin biosynthesis by light been examined [20]. The lycopene cyclase did not show higher protein levels, whereas the mRNA steady state levels of L-carotene ketolase and of the IPP isomerases were upregulated in response to higher light intensities. In the present publication, the isolation and characterization of a cDNA coding for a Haematococcus carotenoid hydroxylase is described. Heterologous complementation and astaxanthin production in E. coli as well as the increased mRNA steady state levels during cyst cell formation indicated that this carotenoid hydroxylase is involved in the biosynthesis of astaxanthin in H. pluvialis. 2. Materials and methods 2.1. Strains, plasmids and growth conditions Haematococcus pluvialis Flotow NIES-144 was obtained from the National Institute for Environmental Studies (NIES), Tsukuba, Japan. The basal medium (pH 6.8) for growth of H. pluvialis contained 1.2 g sodium acetate, 2.0 g yeast extract, 0.4 g L-asparagine, 0.2 g MgCl2 c6H2 O, 0.01 g FeSO4 c7H2 O and 0.02 g CaCl2 c2H2 O per litre [3]. H. pluvialis was grown at 20³C under a dark/light cycle of 12 h light (20 WE/m2 s) and 12 h dark for 4 days. For induction of astaxanthin biosynthesis and cyst cell formation, sodium acetate and FeSO4 were added after 4 days at a ¢nal concentration of 45 mM and 450 WM, respectively. After addition, light conditions were changed to continuous light at 125 WE/m2 s according to [13]. E. coli strain JM101 was used as a host for the complementation experiments with plasmids pACCAR16vcrtX, pRKbkt1 and L-carotene hydroxylase. Plasmid pACCAR16vcrtX harbours the carotenoid biosynthesis genes crtE, crtB, crtI, and crtY from Erwinia uredovora and resulted in biosynthesis of Lcarotene [8,15]. Plasmid pRKbkt1 carries the L-carotene ketolase (bkt) cDNA from H. pluvialis [13]. Cultures of E. coli JM101 containing the di¡erent
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plasmids were grown in LB medium at 28³C for 48 h and ampicillin (50 Wg/ml), chloramphenicol (30 Wg/ ml), tetracycline (10 Wg/ml) and isopropyl-L-D-thiogalactopyranoside (0.5 mM) were added as required [21]. 2.2. Construction of H. pluvialis VcDNA expression libraries, screening and DNA sequencing For the construction of cDNA libraries, H. pluvialis RNAs were extracted either from vegetative cells or from cyst cells (induction of cyst cell formation for 8 h) as described below. After puri¢cation of poly(A)RNA and synthesis of cDNAs, two VZAP expression libraries were constructed with the cDNA Synthesis and ZAP-cDNA Gigapack III Gold Cloning kit (Stratagene). A cDNA fragment of L-carotene hydroxylase from Arabidopsis thaliana [11] (bases 121 to 743; kindly provided by Dr. S. Ro«mer, Konstanz, Germany) which was ampli¢ed by reverse transcription^polymerase chain reaction using speci¢c oligonucleotides was employed as a heterologous probe in the screening procedure. Probe labelling and plaque hybridization was carried out according to the instructions in the DIG Nonradioactive Nucleic Acid Labelling and Detection system (Boehringer Mannheim). After puri¢cation and in vivo excision using the ExAssist/SOLR system (Stratagene), the positive cDNA clone was further utilized for complementation experiments and DNA sequencing. The nucleotide sequence of the H. pluvialis L-carotene hydroxylase cDNA was determined for both strands using the Abi Prism Dye Terminator Cycle Sequencing Ready Reaction kit (Perkin^ Elmer). The analysis of nucleotide and derived amino acid sequences as well as multiple alignments were carried out using the PC/Gene program (IntelliGenetics). Minor changes for multiple alignments were subsequently introduced. 2.3. Northern blot analysis After 4 days of growth, the H. pluvialis cells were collected by centrifugation either directly or after varying induction times of astaxanthin biosynthesis. The cells were frozen and subsequently powdered under liquid nitrogen. RNA was then isolated according to the miniprep RNA extraction procedure
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described by Sokolowsky et al. [22]. For Northern blot analysis, total RNA (10 Wg) was denatured in formaldehyde, electrophoresed on a 1% agarose gel containing 6% formaldehyde, transferred to Hybond N+ membrane (Amersham) and hybridized in the presence of 50% formamide after addition of 1.5U106 cpm/ml of 32 P-labelled probes. 2.4. Carotenoid extraction and HPLC analysis For the isolation of carotenoids (carotenes and hydroxylated products) from E. coli, the freeze-dried cells were extracted twice with acetone at 55³C for 15 min. The combined extracts were then partitioned into diethylether/petrol (b.p. 35^80³C) (1:9, v/v), evaporated to dryness and separated on a nucleosil 100-5 C18 column (Macherey^Nagel) with acetonitrile/methanol/2-propanol (85:10:5, v/v/v) as the eluent for the separation of L-carotene and hydroxylated products. For the separation of keto carotenoids, acetonitrile/methanol/H2 O (50:44:6, v/ v/v) was applied as an eluent 1 for 22 min and methanol as the eluent 2. Spectra were recorded directly from elution peaks using a Waters 994 diode array detector. Total carotenoids from Haematococcus cells were isolated as already described and astaxanthin as well as astaxanthin esters were quanti¢ed after HPLC separation. Standards for HPLC analysis such as L-carotene, astaxanthin and zeaxanthin were purchased either from Sigma or Roth. 2.5. Nucleotide sequence accession number The EMBL GenBank accession number for the L-carotene hydroxylase cDNA reported in this paper is AF162276. 3. Results and discussion 3.1. Isolation and DNA- and amino acid sequence of L-carotene hydroxylase from H. pluvialis For the isolation of carotenoid biosynthesis genes from H. pluvialis, two cDNA libraries were constructed in the VZap vector. For the vegetative cell library, RNA was extracted after 4 days of growth under low light conditions. The cyst cell library was
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Fig. 1. Proposed astaxanthin biosynthetic pathway in H. pluvialis according to in vivo complementation studies [16]. Bold arrows indicate enzymatic reactions carried out by L-carotene hydroxylase. All the other reactions are either carried out by L-carotene ketolase (solid arrows) or indicate biosynthetic steps unlikely to occur in H. pluvialis (broken arrows). Additional non-accumulating intermediates (e.g., hydroxyechinenone) were omitted.
constructed using RNA which was extracted after induction of cyst cell formation and astaxanthin biosynthesis for an additional 8 h. Induction was carried out by the addition of acetate and ferrous sulfate according to [3]. The addition of acetate seems to cause a high carbon/nitrogen ratio and consequently a relative de¢ciency in nitrogen. The addition of Fe2 is presumed to result in the formation of active oxygen species via the Fenton reaction [3]. Under these conditions, the morphological change of vegetative cells into cyst cells and the biosynthesis of astaxan-
thin were shown to proceed rapidly. Therefore, the mRNA steady state levels of genes speci¢cally involved in the biosynthesis of astaxanthin could be expected to be high at this stage. For the screening procedure, a cDNA fragment of A. thaliana L-carotene hydroxylase was used which had been isolated and characterized previously [11]. In spite of extensive screening of both the vegetative and the cyst cell library, only one positive plaque was isolated from the cyst cell library. Sequence analysis of the entire cDNA insert revealed a 1608 base pair (bp) long
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Fig. 2. Nucleotide and deduced amino acid sequences of the cDNA encoding L-carotene hydroxylase from H. pluvialis. The ¢rst ATG codon in frame is underlined.
fragment including a 23 bp poly(A) tail. The DNA sequence shared signi¢cant identity with the A. thaliana L-carotene hydroxylase cDNA (59% identity over 346 bp). The cDNA revealed one long open
reading frame which extends from the beginning of the cDNA to a stop codon at base 969 (Fig. 2), indicating that this cDNA may not represent the entire open reading frame. The ¢rst ATG start codon
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Fig. 3. Amino acid sequence alignment of the H. pluvialis L-carotene hydroxylase with the known bacterial and plant L-carotene hydroxylases. Amino acid residues which were either well or perfectly conserved in all sequences are indicated by (.) and (*) below the alignment, respectively. Identical amino acids are printed in bold. Conserved histidine motifs are shown above the sequence. A highly conserved motif is underlined. GenBank accession numbers: A. thaliana, U58919; C. annuum Ca1, Y09225; C. annuum Ca2, Y09722; Alcaligenes sp., D58422; Agrobacterium aurianticum, D58420; Erwinia herbicola, M87280; Erwinia uredovora, D90087.
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for this open reading frame was found at nucleotide position 90. In contrast to the higher plant cDNAs encoding L-carotene hydroxylases, the H. pluvialis cDNA showed a very long nucleotide sequence which is due to a long 3P non-coding region (A. thaliana, 1156 bp; C. annuum, 1112 bp and 1044 bp; H. pluvialis, 1608 bp). An alignment of the deduced amino acid sequence of H. pluvialis L-carotene hydroxylase with other carotene hydroxylases from bacteria and higher plants is shown in Fig. 3. The only carotene hydroxylase sequence which has been omitted in Fig. 3 is the L-carotene hydroxylase of the cyanobacteria Synechocystis sp. PCC6803 [15]. This protein revealed only limited sequence homologies to the L-carotene hydroxylases presented in Fig. 3. In contrast, it was reported to show sequence similarities with the L-carotene ketolase of H. pluvialis, an enzyme which is also involved in astaxanthin biosynthesis (Fig. 1). The predicted amino acid sequence for the H. pluvialis L-carotene hydroxylase revealed an overall homology to the three known plant L-carotene hydroxylases from A. thaliana and from C. annuum (38% identity). A lower homology was found to the prokaryote carotenoid hydroxylases (32^34% identities). The four conserved histidine motifs which have been described [12] and the highly conserved so called motif 1 (amino acids HDGLVHXRXP; [11]) are also present in the H. pluvialis protein. These histidine residues were proposed to be involved in iron binding and their importance for the hydroxylation reaction was proven by site-directed mutagenesis [12]. The H. pluvialis L-carotene hydroxylase revealed a N-terminal extension when compared to the bacterial hydroxylases which has also been observed for the higher plant enzymes. Due to putative localization of the higher plant enzymes in the chloroplast, a function as chloroplast targeting sequence has been assumed [11]. However, the sequence similarities between the algal and plant enzymes extend for about 50 amino acid residues towards the N-terminus indicating an involvement of this sequence in the enzymatic activity (Fig. 3). In support of this idea, it has been shown for the Arabidopsis L-carotene hydroxylase that a part of this N-terminal region is necessary for a fully functional enzyme. Furthermore, a carotenoid hydroxylase implicated in astaxanthin biosynthesis may be expected to be localized in the cytosol as has been proposed for the
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Fig. 4. HPLC separation of carotenoid pigments extracted from E. coli cells carrying either plasmid pACCAR16vcrtX only (A) or plasmid pACCAR16vcrtX together with L-carotene hydroxylase from H. pluvialis (B). The following carotenoids were identi¢ed by their absorption spectra and their retention times, as compared to standards: L-carotene, L-cryptoxanthin and zeaxanthin, all revealing absorption maxima at 425 nm, 452 nm and 480 nm.
H. pluvialis L-carotene ketolase [13]. Further experiments are required to address these questions. 3.2. Heterologous complementation of L-carotene hydroxylase in E. coli In order to examine the catalytic activities of the H. pluvialis L-carotene hydroxylase, E. coli strains were used which had been genetically engineered to produce various carotenoids [13,15]. Transformation of plasmid pACCAR16vcrtX which contained the crtE, crtB, crtI and crtY genes from E. uredovora in E. coli resulted in the accumulation of L-carotene (Fig. 4A). After co-transformation of plasmids pACCAR16vcrtX and the plasmid containing the entire L-carotene hydroxylase cDNA from H. pluvialis, the corresponding E. coli transformants were shown to produce L-cryptoxanthin and zeaxanthin (Fig. 4B). The conversion ratio between L-carotene and the hydroxylated products was similar to the conversion ratio which has previously been described for the higher plant hydroxylases from Arabidopsis and Capsicum [11,12]. In enzyme studies using the L-carotene ketolase
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from Haematococcus, it was shown that the latter enzyme mainly converted L-carotene into canthaxanthin (Fig. 1, [14,16^18]). However, the hydroxylated carotenoids such as L-cryptoxanthin and zeaxanthin were only poor substrates for the ketolase. Therefore, a carotenoid hydroxylase which is involved in astaxanthin biosynthesis should also be capable of catalysing the conversion from canthaxanthin to astaxanthin as previously proposed [14]. To investigate this hypothesis, a second co-transformation experiment was designed. Co-transformation of plasmid pACCAR16vcrtX and plasmid pRKbkt1 (containing the Haematococcus L-carotene ketolase [13]) in E. coli resulted in the biosynthesis of the keto carotenoid canthaxanthin in addition to small amounts of L-carotene (Fig. 5A, peaks 4 and 6). After transfor-
Fig. 6. Expression of L-carotene hydroxylase cDNA in H. pluvialis and astaxanthin biosynthesis before and after induction of cyst cell formation. The H. pluvialis L-carotene hydroxylase was used as speci¢c probe (A). For comparison, total RNA on the agarose gel was stained with ethidium bromide (B). In addition, the accumulation of astaxanthin was examined (C).
Fig. 5. HPLC separation of carotenoid pigments extracted from E. coli cells after transformation with plasmids pACCAR16vcrtX and pRKbkt1 (A) and with plasmids pACCAR16vcrtX, pRKbkt1 and L-carotene hydroxylase from H. pluvialis (B). For comparison, an astaxanthin standard was also separated (C). HPLC separation was carried out using acetonitrile/methanol/H2 O (50:44:6, v/v/v) as eluent 1 for 22 min and methanol as eluent 2. The following carotenoids were identi¢ed by their absorption spectra and their retention times, as compared to standards: 1, astaxanthin (absorbance maximum, 480 nm); 2, probably adonixanthin (470 nm); 3, zeaxanthin (425 nm, 452 nm, 480 nm); 4, canthaxanthin (475 nm) ; 5, L-cryptoxanthin (425 nm, 452 nm, 480 nm), 6, L-carotene (425 nm, 452 nm, 480 nm).
mation of this E. coli strain with a third plasmid containing the Haematococcus carotenoid hydroxylase cDNA fragment, several carotenoids were detected by HPLC analysis (Fig. 5B). First of all, canthaxanthin (peak 4), L-cryptoxanthin (peak 5) and zeaxanthin (peak 3) were identi¢ed. These xanthophylls correspond to the intermediate and end products of L-carotene ketolase and hydroxylase, respectively, as shown in Figs. 4B and 5A. In addition, the E. coli transformant produced astaxanthin (Fig. 5B, peak 1). Astaxanthin was identi¢ed by the absorbance maximum of 480 nm and the retention time which corresponded to the retention time of a purchased astaxanthin standard (Fig. 5C, peak 1). Furthermore, a second additional xanthophyll was
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found which was identi¢ed as adonixanthin because of a higher retention time in comparison to astaxanthin and the spectrum with only one maximum at 470 nm (Fig. 5B, peak 2). In consequence, the Haematococcus carotenoid hydroxylase seems to be a multifunctional enzyme, which accepts not only Lcarotene but also keto carotenoids such as canthaxanthin as possible substrates. This is in accordance with results from in vitro studies of L-carotene ketolase from H. pluvialis which showed that the ketolase has a higher catalytic speci¢city for non-hydroxylated substrates such as L-carotene and echinenone [17]. Due to this higher catalytic speci¢ty of L-carotene ketolase, adonixanthin and zeaxanthin detected in Fig. 5 are proposed to represent ¢nal products which can not be further converted to astaxanthin. This also means that adonixanthin is not derived from zeaxanthin but is produced via other keto carotenoid intermediates (hydroxyechinenone). The biosynthesis of astaxanthin in E. coli has also been reported using bacterial carotenoid hydroxylases from E. uredovora which revealed the same enzymatic activities as the carotenoid hydroxylase from H. pluvialis. [9,13,14]. In contrast, the hydroxylation of keto carotenoids has not yet been described for the higher plant hydroxylases from Arabidopsis and Capsicum [11,12]. 3.3. Expression of L-carotene hydroxylase during the induction of astaxanthin biosynthesis in H. pluvialis In Northern blot analysis, the expression pattern of L-carotene hydroxylase was examined using RNA extracted from cells at di¡erent stages of cyst cell and astaxanthin biosynthesis induction (Fig. 6). No transcript was detected in the vegetative cells (Fig. 6A). In contrast, the Haematococcus cells clearly revealed a hydroxylase transcript 3 h after induction of astaxanthin biosynthesis and cyst cell formation by high light and by the addition of ferrous sulfate and acetate. An additional strong increase in the hydroxylase mRNA steady state levels was observed after 6 h induction time. For comparison, the accumulation of astaxanthin was also examined over the same period of induction (Fig. 6C). Only a very small increase was observed after 3 h induction, whereas a signi¢-
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cant increase in astaxanthin was found after an induction for 6 h. The latter result is a con¢rmation of the kinetics of astaxanthin accumulation already published in which a ¢rst signi¢cant increase of astaxanthin was observed several hours after induction [3]. The maximum astaxanthin accumulation was reported to occur only 2 to 3 days after the induction of cyst cell formation. In conclusion, the Haematococcus L-carotene hydroxylase characterized in the present publication reveals all the features of a carotenoid hydroxylase involved in astaxanthin biosynthesis. Firstly, the enzyme was shown to be capable of astaxanthin biosynthesis in complementation experiments. Furthermore, the transcript of the carotenoid hydroxylase revealed a strong induction during the process of astaxanthin accumulation. An additional function in the biosynthesis of zeaxanthin during vegetative growth can be presumed although no transcript was detected (Fig. 6A). A minor undetectable expression of the same transcript in the vegetative cells may be su¤cient for xanthophyll production. The fact that the Haematococcus carotenoid hydroxylase revealed a bifunctional catalytic activity hydroxylating not only canthaxanthin but also L-carotene, as shown in Fig. 4, supports the latter presumption. Alternatively, another as yet not identi¢ed hydroxylase may exist which is transcribed only in vegetative cells and which is responsible for the biosynthesis of the xanthophylls involved in photosynthesis. Acknowledgements This work was only possible due to the generous support from Prof. Dr. P. Bo«ger, Konstanz, Germany. I am grateful to Dr. M. Albrecht, Frankfurt, Germany for the gift of the plasmid pRKbkt1. Furthermore, I wish to thank F. Kirsch, Konstanz, Germany for her help in the laboratory. Due thanks are expressed to Dr. N. Misawa, Kirin Brewery Co., Yokohama, Japan for his advice on the H. pluvialis cDNA library construction and for the gift of the plasmids for complementation in E. coli. I am also grateful to Dr. S. Ro«mer, Konstanz, Germany for providing the cDNA fragment of L-carotene hydroxylase from Arabidopsis thaliana.
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BBAEXP 93288 17-8-99